The results are compared and check at the numerical precision levels. Some small discrepancy can appear when the macro is executed on different architectures where it has been calibrated (Power PC G5) The macro is divided in 4 parts:
************************************************************************
Vector 3D Test
************************************************************************
Test Cartesian-Polar : ........ OK
Test Cartesian-CylindricalEta : ........ OK
Test Cartesian-Cylindrical : ........ OK
Test Operations : ............. OK
Test Setters : ...... OK
Test Linear Algebra conversion: . OK
************************************************************************
Point 3D Tests
************************************************************************
Test Cartesian-Polar : ........ OK
Test Polar-CylindricalEta : ........ OK
Test operations : ..... OK
************************************************************************
Lorentz Vector Tests
************************************************************************
Test XYZT - PtEtaPhiE Vectors: .......... OK
Test XYZT - PtEtaPhiM Vectors: .......... OK
Test PtEtaPhiE - PxPyPzM Vect.: .......... OK
Test operations : ............ OK
Test Setters : ........ OK
************************************************************************
Utility Function Tests
************************************************************************
Test Vector utility functions : .... OK
Test Point utility functions : .... OK
LorentzVector utility funct.: ... OK
************************************************************************
Rotation and Transformation Tests
************************************************************************
Test Vector Rotations : ............... OK
Test Axial Rotations : ............... OK
Test Rotations by a PI angle : ....... OK
Test Inversions : ............... OK
Test rectify : . OK
Test Transform3D : .............. OK
Test Plane3D : ........ OK
Test LorentzRotation : .......... OK
Test Boost : ............. OK
Number of tests 224 failed = 0
int ntest = 0;
int nfail = 0;
int ok = 0;
int compare(
double v1,
double v2,
const char*
name,
double Scale = 1.0) {
ntest = ntest + 1;
double eps = Scale* 2.22044604925031308e-16;
int iret = 0;
if (delta < 0 ) delta = - delta;
if (
v1 == 0 ||
v2 == 0) {
if (delta > eps ) {
iret = 1;
}
}
else {
if ( delta/
d > eps && delta > eps )
iret = 1;
}
if (iret == 0)
std::cout << ".";
else {
int pr = std::cout.precision (18);
int discr;
discr =
int(delta/
d/eps);
else
std::cout <<
"\nDiscrepancy in " <<
name <<
"() : " <<
v1 <<
" != " <<
v2 <<
" discr = " << discr
<< " (Allowed discrepancy is " << eps << ")\n";
std::cout.precision (pr);
nfail = nfail + 1;
}
return iret;
}
int testVector3D() {
std::cout << "\n************************************************************************\n "
<< " Vector 3D Test"
<< "\n************************************************************************\n";
std::cout << "Test Cartesian-Polar : " ;
ok = 0;
ok+= compare(
v1.X(),
v2.X(),
"x");
ok+= compare(
v1.Y(),
v2.Y(),
"y");
ok+= compare(
v1.Z(),
v2.Z(),
"z");
ok+= compare(
v1.Phi(),
v2.Phi(),
"phi");
ok+= compare(
v1.Theta(),
v2.Theta(),
"theta");
ok+= compare(
v1.R(),
v2.R(),
"r");
ok+= compare(
v1.Eta(),
v2.Eta(),
"eta");
ok+= compare(
v1.Rho(),
v2.Rho(),
"rho");
if (ok == 0) std::cout << "\t OK " << std::endl;
std::cout << "Test Cartesian-CylindricalEta : ";
ok = 0;
ok+= compare(
v1.X(),
v3.X(),
"x");
ok+= compare(
v1.Y(),
v3.Y(),
"y");
ok+= compare(
v1.Z(),
v3.Z(),
"z");
ok+= compare(
v1.Phi(),
v3.Phi(),
"phi");
ok+= compare(
v1.Theta(),
v3.Theta(),
"theta");
ok+= compare(
v1.R(),
v3.R(),
"r");
ok+= compare(
v1.Eta(),
v3.Eta(),
"eta");
ok+= compare(
v1.Rho(),
v3.Rho(),
"rho");
if (ok == 0) std::cout << "\t OK " << std::endl;
std::cout << "Test Cartesian-Cylindrical : ";
ok = 0;
ok+= compare(
v1.X(),
v4.X(),
"x");
ok+= compare(
v1.Y(),
v4.Y(),
"y");
ok+= compare(
v1.Z(),
v4.Z(),
"z");
ok+= compare(
v1.Phi(),
v4.Phi(),
"phi");
ok+= compare(
v1.Theta(),
v4.Theta(),
"theta");
ok+= compare(
v1.R(),
v4.R(),
"r");
ok+= compare(
v1.Eta(),
v4.Eta(),
"eta");
ok+= compare(
v1.Rho(),
v4.Rho(),
"rho");
if (ok == 0) std::cout << "\t OK " << std::endl;
std::cout << "Test Operations : " ;
ok = 0;
ok+= compare(
Dot,
v1.Mag2(),
"dot" );
ok+= compare( vcross.
R(), 0,
"cross" );
ok+= compare(
v1.R(), vscale2.
R(),
"scale");
ok+= compare(
v2.Phi(),vu.
Phi(),
"unit Phi");
ok+= compare(
v2.Theta(),vu.
Theta(),
"unit Theta");
ok+= compare(1.0,vu.
R(),
"unit ");
ok+= compare( q4.
X(), q1.
X(),
"op X" );
ok+= compare( q4.
Y(), q1.
Y(),
"op Y" );
ok+= compare( q4.
Z(), q1.
Z(),
"op Z" );
ok+= compare( w1 ==
v1,
static_cast<double>(
true),
"== XYZ");
ok+= compare( w2 ==
v2,
static_cast<double>(
true),
"== Polar");
ok+= compare( w3 ==
v3,
static_cast<double>(
true),
"== RhoEtaPhi");
ok+= compare( w4 ==
v4,
static_cast<double>(
true),
"== RhoZPhi");
if (ok == 0) std::cout << "\t OK " << std::endl;
std::cout << "Test Setters : " ;
q2.SetXYZ(q1.
X(), q1.
Y(), q1.
Z() );
ok+= compare( q2.X(), q1.
X(),
"setXYZ X" );
ok+= compare( q2.Y(), q1.
Y(),
"setXYZ Y" );
ok+= compare( q2.Z(), q1.
Z(),
"setXYZ Z" );
q2.SetCoordinates( 2.0*q1.
Rho(), q1.
Eta(), q1.
Phi() );
ok+= compare( q2.X(), q1s.
X(),
"set X" );
ok+= compare( q2.Y(), q1s.
Y(),
"set Y" );
ok+= compare( q2.Z(), q1s.
Z(),
"set Z" );
if (ok == 0) std::cout << "\t\t OK " << std::endl;
std::cout << "Test Linear Algebra conversion: " ;
vxyz1.Coordinates().GetCoordinates(vla1.GetMatrixArray() );
vla2[0] = 1.; vla2[1] = -2.; vla2[2] = 1.;
ok = 0;
double prod1 = vxyz1.Dot(vxyz2);
double prod2 = vla1*vla2;
ok+= compare( prod1, prod2, "la test" );
if (ok == 0) std::cout << "\t\t OK " << std::endl;
return ok;
}
int testPoint3D() {
std::cout << "\n************************************************************************\n "
<< " Point 3D Tests"
<< "\n************************************************************************\n";
std::cout << "Test Cartesian-Polar : ";
ok = 0;
ok+= compare(p1.x(), p2.X(), "x");
ok+= compare(p1.y(), p2.Y(), "y");
ok+= compare(p1.z(), p2.Z(), "z");
ok+= compare(p1.phi(), p2.Phi(), "phi");
ok+= compare(p1.theta(), p2.Theta(), "theta");
ok+= compare(p1.r(), p2.R(), "r");
ok+= compare(p1.eta(), p2.Eta(), "eta");
ok+= compare(p1.rho(), p2.Rho(), "rho");
if (ok == 0) std::cout << "\t OK " << std::endl;
std::cout << "Test Polar-CylindricalEta : ";
ok = 0;
ok+= compare(p2.X(), p3.X(), "x");
ok+= compare(p2.Y(), p3.Y(), "y");
ok+= compare(p2.Z(), p3.Z(), "z",3);
ok+= compare(p2.Phi(), p3.Phi(), "phi");
ok+= compare(p2.Theta(), p3.Theta(), "theta");
ok+= compare(p2.R(), p3.R(), "r");
ok+= compare(p2.Eta(), p3.Eta(), "eta");
ok+= compare(p2.Rho(), p3.Rho(), "rho");
if (ok == 0) std::cout << "\t OK " << std::endl;
std::cout << "Test operations : ";
double Dot = p1.Dot(vperp);
ok+= compare(
Dot, 0.0,
"dot", 10 );
ok+= compare( vcross.
R(), p1.R(),
"cross mag" );
ok+= compare( vcross.
Dot(vperp), 0.0,
"cross dir" );
ok+= compare( p1.R(), pscale2.
R(),
"scale");
ok+= compare( p1 == pscale2, static_cast<double>(true), "== Point");
if (ok == 0) std::cout << "\t OK " << std::endl;
return ok;
}
int testLorentzVector() {
std::cout << "\n************************************************************************\n "
<< " Lorentz Vector Tests"
<< "\n************************************************************************\n";
std::cout << "Test XYZT - PtEtaPhiE Vectors: ";
ok = 0;
ok+= compare(
v1.Px(),
v2.X(),
"x");
ok+= compare(
v1.Py(),
v2.Y(),
"y");
ok+= compare(
v1.Pz(),
v2.Z(),
"z", 2);
ok+= compare(
v1.E(),
v2.T(),
"e");
ok+= compare(
v1.Phi(),
v2.Phi(),
"phi");
ok+= compare(
v1.Theta(),
v2.Theta(),
"theta");
ok+= compare(
v1.Pt(),
v2.Pt(),
"pt");
ok+= compare(
v1.M(),
v2.M(),
"mass", 5);
ok+= compare(
v1.Et(),
v2.Et(),
"et");
ok+= compare(
v1.Mt(),
v2.Mt(),
"mt", 3);
if (ok == 0) std::cout << "\t OK " << std::endl;
std::cout << "Test XYZT - PtEtaPhiM Vectors: ";
ok = 0;
ok+= compare(
v1.Px(),
v3.X(),
"x");
ok+= compare(
v1.Py(),
v3.Y(),
"y");
ok+= compare(
v1.Pz(),
v3.Z(),
"z", 2);
ok+= compare(
v1.E(),
v3.T(),
"e");
ok+= compare(
v1.Phi(),
v3.Phi(),
"phi");
ok+= compare(
v1.Theta(),
v3.Theta(),
"theta");
ok+= compare(
v1.Pt(),
v3.Pt(),
"pt");
ok+= compare(
v1.M(),
v3.M(),
"mass", 5);
ok+= compare(
v1.Et(),
v3.Et(),
"et");
ok+= compare(
v1.Mt(),
v3.Mt(),
"mt", 3);
if (ok == 0) std::cout << "\t OK " << std::endl;
std::cout << "Test PtEtaPhiE - PxPyPzM Vect.: ";
ok = 0;
ok+= compare(
v4.Px(),
v3.X(),
"x");
ok+= compare(
v4.Py(),
v3.Y(),
"y");
ok+= compare(
v4.Pz(),
v3.Z(),
"z",2);
ok+= compare(
v4.E(),
v3.T(),
"e");
ok+= compare(
v4.Phi(),
v3.Phi(),
"phi");
ok+= compare(
v4.Theta(),
v3.Theta(),
"theta");
ok+= compare(
v4.Pt(),
v3.Pt(),
"pt");
ok+= compare(
v4.M(),
v3.M(),
"mass",5);
ok+= compare(
v4.Et(),
v3.Et(),
"et");
ok+= compare(
v4.Mt(),
v3.Mt(),
"mt",3);
if (ok == 0) std::cout << "\t OK " << std::endl;
std::cout << "Test operations : ";
ok = 0;
ok+= compare(
Dot,
v1.M2(),
"dot" , 10 );
ok+= compare(
v1.M(), vscale2.
M(),
"scale");
ok+= compare( q4.
x(), q1.
X(),
"op X" );
ok+= compare( q4.
y(), q1.
Y(),
"op Y" );
ok+= compare( q4.
z(), q1.
Z(),
"op Z" );
ok+= compare( q4.
t(), q1.
E(),
"op E" );
ok+= compare( w1 ==
v1,
static_cast<double>(
true),
"== PxPyPzE");
ok+= compare( w2 ==
v2,
static_cast<double>(
true),
"== PtEtaPhiE");
ok+= compare( w3 ==
v3,
static_cast<double>(
true),
"== PtEtaPhiM");
ok+= compare( w4 ==
v4,
static_cast<double>(
true),
"== PxPyPzM");
ok += compare(
b.R(), beta,
"beta" );
ok += compare( gamma, 1./
sqrt( 1 - beta*beta ),
"gamma");
if (ok == 0) std::cout << "\t OK " << std::endl;
std::cout << "Test Setters : " ;
q2.SetXYZT(q1.
Px(), q1.
Py(), q1.
Pz(), q1.
E() );
ok+= compare( q2.X(), q1.
X(),
"setXYZT X" );
ok+= compare( q2.Y(), q1.
Y(),
"setXYZT Y" );
ok+= compare( q2.Z(), q1.
Z(),
"setXYZT Z" ,2);
ok+= compare( q2.T(), q1.
E(),
"setXYZT E" );
q2.SetCoordinates( 2.0*q1.
Rho(), q1.
Eta(), q1.
Phi(), 2.0*q1.
E() );
ok+= compare( q2.X(), q1s.
X(),
"set X" );
ok+= compare( q2.Y(), q1s.
Y(),
"set Y" );
ok+= compare( q2.Z(), q1s.
Z(),
"set Z" ,2);
ok+= compare( q2.T(), q1s.
T(),
"set E" );
if (ok == 0) std::cout << "\t OK " << std::endl;
return ok;
}
int testVectorUtil() {
std::cout << "\n************************************************************************\n "
<< " Utility Function Tests"
<< "\n************************************************************************\n";
std::cout << "Test Vector utility functions : ";
ok = 0;
ok += compare( VectorUtil::DeltaPhi(
v1,
v2), 1.0,
"deltaPhi Vec");
ok += compare( VectorUtil::DeltaR(
v1,
v2),
sqrt(2.0),
"DeltaR Vec");
ok += compare( VectorUtil::CosTheta(
v1,vperp), 0.0,
"costheta Vec");
if (ok == 0) std::cout << "\t\t OK " << std::endl;
std::cout << "Test Point utility functions : ";
ok = 0;
ok += compare( VectorUtil::DeltaPhi(p1,p2), 1.0, "deltaPhi Point");
p2 = p2cyl;
ok += compare( VectorUtil::DeltaR(p1,p2),
sqrt(2.0),
"DeltaR Point");
ok += compare( VectorUtil::CosTheta(p1,pperp), 0.0, "costheta Point");
ok += compare( VectorUtil::Angle(p1,pperp),
TMath::PiOver2(),
"angle Point");
if (ok == 0) std::cout << "\t\t OK " << std::endl;
std::cout << "LorentzVector utility funct.: ";
ok = 0;
ok += compare( VectorUtil::DeltaPhi(q1,q2), 1.0, "deltaPhi LVec");
ok += compare( VectorUtil::DeltaR(q1,q2),
sqrt(2.0),
"DeltaR LVec");
ok += compare( VectorUtil::InvariantMass(q1,q2), qsum.
M(),
"InvMass");
if (ok == 0) std::cout << "\t\t OK " << std::endl;
return ok;
}
int testRotation() {
std::cout << "\n************************************************************************\n "
<< " Rotation and Transformation Tests"
<< "\n************************************************************************\n";
std::cout << "Test Vector Rotations : ";
ok = 0;
ok+= compare(
v1.X(),
v2.X(),
"x",2);
ok+= compare(
v1.Y(),
v2.Y(),
"y",2);
ok+= compare(
v1.Z(),
v2.Z(),
"z",2);
ok+= compare(
v1.X(),
v3.X(),
"x",2);
ok+= compare(
v1.Y(),
v3.Y(),
"y",2);
ok+= compare(
v1.Z(),
v3.Z(),
"z",2);
ok+= compare(
v1.X(),
v4.X(),
"x",5);
ok+= compare(
v1.Y(),
v4.Y(),
"y",5);
ok+= compare(
v1.Z(),
v4.Z(),
"z",5);
ok+= compare(
v1.X(), v5.
X(),
"x",2);
ok+= compare(
v1.Y(), v5.
Y(),
"y",2);
ok+= compare(
v1.Z(), v5.
Z(),
"z",2);
double rdata[9];
r2.GetComponents(rdata, rdata+9);
double vdata[3];
ok+= compare(
v1.X(), v6.
X(),
"x");
ok+= compare(
v1.Y(), v6.
Y(),
"y");
ok+= compare(
v1.Z(), v6.
Z(),
"z");
if (ok == 0) std::cout << "\t OK " << std::endl;
else std::cout << std::endl;
std::cout << "Test Axial Rotations : ";
ok = 0;
RotationZYX rzyx( rz.Angle(), ry.Angle(), rx.Angle() );
ok+= compare(vrot1.
X(), vrot2.
X(),
"x");
ok+= compare(vrot1.
Y(), vrot2.
Y(),
"y");
ok+= compare(vrot1.
Z(), vrot2.
Z(),
"z");
vrot2 = qx * qy * qz *
v;
ok+= compare(vrot1.
X(), vrot2.
X(),
"x",2);
ok+= compare(vrot1.
Y(), vrot2.
Y(),
"y",2);
ok+= compare(vrot1.
Z(), vrot2.
Z(),
"z",2);
ok+= compare(vrot1.
X(), vrot2.
X(),
"x");
ok+= compare(vrot1.
Y(), vrot2.
Y(),
"y");
ok+= compare(vrot1.
Z(), vrot2.
Z(),
"z");
vrot1 = rz * ry * rx *
v;
vrot2 = r3z * r3y * r3x *
v;
ok+= compare(vrot1.
X(), vrot2.
X(),
"x");
ok+= compare(vrot1.
Y(), vrot2.
Y(),
"y");
ok+= compare(vrot1.
Z(), vrot2.
Z(),
"z");
XYZPoint vinv1 = rx.Inverse()*ry.Inverse()*rz.Inverse()*vrot1;
ok+= compare(vinv1.
X(),
v.X(),
"x",2);
ok+= compare(vinv1.
Y(),
v.Y(),
"y");
ok+= compare(vinv1.
Z(),
v.Z(),
"z");
if (ok == 0) std::cout << "\t OK " << std::endl;
else std::cout << std::endl;
std::cout << "Test Rotations by a PI angle : ";
ok = 0;
double b[4] = { 6,8,10,3.14159265358979323 };
ok+= compare(arPi.Axis().X(), a1.
Axis().
X(),
"x");
ok+= compare(arPi.Axis().Y(), a1.
Axis().
Y(),
"y");
ok+= compare(arPi.Axis().Z(), a1.
Axis().
Z(),
"z");
ok+= compare(arPi.Angle(), a1.
Angle(),
"angle");
ok+= compare(ePi.
Phi(), e1.
Phi(),
"phi");
ok+= compare(ePi.
Psi(), e1.
Psi(),
"ps1");
if (ok == 0) std::cout << "\t\t OK " << std::endl;
else std::cout << std::endl;
std::cout << "Test Inversions : ";
ok = 0;
ok+= compare(
p.X(),
v.X(),
"x",10);
ok+= compare(
p.Y(),
v.Y(),
"y",10);
ok+= compare(
p.Z(),
v.Z(),
"z",10);
ok+= compare(
p.X(),
v.X(),
"x",10);
ok+= compare(
p.Y(),
v.Y(),
"y",10);
ok+= compare(
p.Z(),
v.Z(),
"z",10);
ok+= compare(
p.X(),
v.X(),
"x",1E9);
ok+= compare(
p.Y(),
v.Y(),
"y",1E9);
ok+= compare(
p.Z(),
v.Z(),
"z",1E9);
ok+= compare(
p.X(),
v.X(),
"x",10);
ok+= compare(
p.Y(),
v.Y(),
"y",10);
ok+= compare(
p.Z(),
v.Z(),
"z",10);
ok+= compare(
p.X(),
v.X(),
"x",10);
ok+= compare(
p.Y(),
v.Y(),
"y",10);
ok+= compare(
p.Z(),
v.Z(),
"z",10);
if (ok == 0) std::cout << "\t OK " << std::endl;
else std::cout << std::endl;
std::cout << "Test rectify : ";
ok = 0;
XYZVector u1(0.999498,-0.00118212,-0.0316611);
ok+= compare(
v.R(), vrr.
R(),
"R",1.E9);
if (ok == 0) std::cout << "\t\t OK " << std::endl;
else std::cout << std::endl;
std::cout << "Test Transform3D : ";
ok = 0;
ok+= compare(pd.
X(), vd.
X(),
"x");
ok+= compare(pd.
Y(), vd.
Y(),
"y");
ok+= compare(pd.
Z(), vd.
Z(),
"z");
double tdata[12];
t.GetComponents(tdata);
double vData[4];
vData[3] = 1;
ok+= compare(pd.
X(), qt(0),
"x");
ok+= compare(pd.
Y(), qt(1),
"y");
ok+= compare(pd.
Z(), qt(2),
"z");
ok+= compare(
p.X(),
v.X(),
"x",10);
ok+= compare(
p.Y(),
v.Y(),
"y",10);
ok+= compare(
p.Z(),
v.Z(),
"z",10);
ok+= compare(
p.X(),
v.X(),
"x",10);
ok+= compare(
p.Y(),
v.Y(),
"y",10);
ok+= compare(
p.Z(),
v.Z(),
"z",10);
ok+= compare( tc == tb*ta, static_cast<double>(true), "== Rot*Tra");
ok+= compare( td == ta*tb, static_cast<double>(true), "== Rot*Tra");
if (ok == 0) std::cout << "\t OK " << std::endl;
else std::cout << std::endl;
std::cout << "Test Plane3D : ";
ok = 0;
ok+= compare(
n.Dot(p2-p1), 0.0,
"n.v12",10);
ok+= compare(
n.Dot(p3-p1), 0.0,
"n.v13",10);
ok+= compare(
n.Dot(p3-p2), 0.0,
"n.v23",10);
ok+= compare(n1.
X(), n2.
X(),
"a",10);
ok+= compare(n1.
Y(), n2.
Y(),
"b",10);
ok+= compare(n1.
Z(), n2.
Z(),
"c",10);
ok+= compare(plane1.
HesseDistance(), plane2.HesseDistance(),
"d",10);
ok += compare(plane1.
Distance(pt1), 0.0,
"distance",10);
if (ok == 0) std::cout << "\t OK " << std::endl;
else std::cout << std::endl;
std::cout << "Test LorentzRotation : ";
ok = 0;
ok+= compare(lv1== lv2,true,"V0==V2");
ok+= compare(lv1== lv2,true,"V1==V2");
double rlData[16];
double lvData[4];
lv.GetCoordinates(lvData);
ok+= compare(lv1.
X(), qlr(0),
"x");
ok+= compare(lv1.
Y(), qlr(1),
"y");
ok+= compare(lv1.
Z(), qlr(2),
"z");
ok+= compare(lv1.
E(), qlr(3),
"t");
ok+= compare(lv0.
X(),
lv.X(),
"x");
ok+= compare(lv0.
Y(),
lv.Y(),
"y");
ok+= compare(lv0.
Z(),
lv.Z(),
"z");
ok+= compare(lv0.
E(),
lv.E(),
"t");
if (ok == 0) std::cout << "\t OK " << std::endl;
else std::cout << std::endl;
std::cout << "Test Boost : ";
ok = 0;
ok+= compare(lvb.
X(), lvb2.
X(),
"x");
ok+= compare(lvb.
Y(), lvb2.
Y(),
"y");
ok+= compare(lvb.
Z(), lvb2.
Z(),
"z");
ok+= compare(lvb.
E(), lvb2.
E(),
"t");
ok+= compare(lvb.
M(),
lv.M(),
"m",50);
lv0 = bst.Inverse() * lvb;
ok+= compare(lv0.
X(),
lv.X(),
"x",5);
ok+= compare(lv0.
Y(),
lv.Y(),
"y",5);
ok+= compare(lv0.
Z(),
lv.Z(),
"z",3);
ok+= compare(lv0.
E(),
lv.E(),
"t",3);
bst.SetComponents( brest.
X(), brest.
Y(), brest.
Z() );
ok+= compare(lvr.
X(), 0.0,
"x",10);
ok+= compare(lvr.
Y(), 0.0,
"y",10);
ok+= compare(lvr.
Z(), 0.0,
"z",10);
ok+= compare(lvr.
M(),
lv.M(),
"m",10);
if (ok == 0) std::cout << "\t OK " << std::endl;
else std::cout << std::endl;
return ok;
}
void mathcoreGenVector() {
testVector3D();
testPoint3D();
testLorentzVector();
testVectorUtil();
testRotation();
std::cout << "\n\nNumber of tests " << ntest << " failed = " << nfail << std::endl;
}
winID h TVirtualViewer3D TVirtualGLPainter p
AxisAngle class describing rotation represented with direction axis (3D Vector) and an angle of rotat...
AxisVector Axis() const
access to rotation axis
Scalar Angle() const
access to rotation angle
AxisAngle Inverse() const
Return inverse of an AxisAngle rotation.
Lorentz boost class with the (4D) transformation represented internally by a 4x4 orthosymplectic matr...
Scalar Theta() const
Polar theta, converting if necessary from internal coordinate system.
Scalar R() const
Polar R, converting if necessary from internal coordinate system.
DisplacementVector3D Unit() const
return unit vector parallel to this (scalar)
Scalar X() const
Cartesian X, converting if necessary from internal coordinate system.
Scalar Y() const
Cartesian Y, converting if necessary from internal coordinate system.
DisplacementVector3D Cross(const DisplacementVector3D< OtherCoords, Tag > &v) const
Return vector (cross) product of two displacement vectors, as a vector in the coordinate system of th...
Scalar Rho() const
Cylindrical transverse component rho.
DisplacementVector3D< CoordSystem, Tag > & SetCoordinates(const Scalar src[])
Set internal data based on a C-style array of 3 Scalar numbers.
Scalar Phi() const
Polar phi, converting if necessary from internal coordinate system.
Scalar Eta() const
Polar eta, converting if necessary from internal coordinate system.
Scalar Z() const
Cartesian Z, converting if necessary from internal coordinate system.
EulerAngles class describing rotation as three angles (Euler Angles).
Scalar Psi() const
Return Psi Euler angle.
Scalar Theta() const
Return Theta Euler angle.
EulerAngles Inverse() const
Return inverse of a rotation.
Scalar Phi() const
Return Phi Euler angle.
Class describing a geometrical plane in 3 dimensions.
Vector Normal() const
Return normal vector to the plane as Cartesian DisplacementVector.
Scalar HesseDistance() const
Return the Hesse Distance (distance from the origin) of the plane or the d coefficient expressed in n...
Scalar Distance(const Point &p) const
Return the signed distance to a Point.
Lorentz transformation class with the (4D) transformation represented by a 4x4 orthosymplectic matrix...
LorentzRotation Inverse() const
Return inverse of a rotation.
void GetComponents(Foreign4Vector &v1, Foreign4Vector &v2, Foreign4Vector &v3, Foreign4Vector &v4) const
Get components into four 4-vectors which will be the (orthosymplectic) columns of the rotation matrix...
Class describing a generic LorentzVector in the 4D space-time, using the specified coordinate system ...
Scalar E() const
return 4-th component (time, or energy for a 4-momentum vector)
BetaVector BoostToCM() const
The beta vector for the boost that would bring this vector into its center of mass frame (zero moment...
Scalar M() const
return magnitude (mass) using the (-,-,-,+) metric.
Scalar Pt() const
return the transverse spatial component sqrt ( X**2 + Y**2 )
Scalar Beta() const
Return beta scalar value.
Scalar Eta() const
pseudorapidity
Scalar Py() const
spatial Y component
Scalar Pz() const
spatial Z component
Scalar Phi() const
azimuthal Angle
Scalar Gamma() const
Return Gamma scalar value.
Scalar Px() const
spatial X component
Class describing a generic position vector (point) in 3 dimensions.
Scalar Y() const
Cartesian Y, converting if necessary from internal coordinate system.
Scalar Z() const
Cartesian Z, converting if necessary from internal coordinate system.
Scalar X() const
Cartesian X, converting if necessary from internal coordinate system.
PositionVector3D< CoordSystem, Tag > & SetCoordinates(const Scalar src[])
Set internal data based on a C-style array of 3 Scalar numbers.
Scalar Dot(const DisplacementVector3D< OtherCoords, Tag > &v) const
Return the scalar (Dot) product of this with a displacement vector in any coordinate system,...
Scalar R() const
Polar R, converting if necessary from internal coordinate system.
Rotation class with the (3D) rotation represented by a unit quaternion (u, i, j, k).
Quaternion Inverse() const
Return inverse of a rotation.
Rotation class with the (3D) rotation represented by a 3x3 orthogonal matrix.
Rotation3D Inverse() const
Return inverse of a rotation.
Rotation class representing a 3D rotation about the X axis by the angle of rotation.
Rotation class representing a 3D rotation about the Y axis by the angle of rotation.
Rotation class with the (3D) rotation represented by angles describing first a rotation of an angle p...
RotationZYX Inverse() const
Return inverse of a rotation.
Rotation class representing a 3D rotation about the Z axis by the angle of rotation.
Element * GetMatrixArray()
double beta(double x, double y)
Calculates the beta function.
VecExpr< UnaryOp< Sqrt< T >, VecExpr< A, T, D >, T >, T, D > sqrt(const VecExpr< A, T, D > &rhs)
constexpr Double_t PiOver2()